Drying Device

ABSTRACT

Drying apparatus includes a housing defining an air inlet and a tortuous airflow passage leading to at least one air outlet. The outlet comprises two upright sets of louvres. An impeller is arranged to draw air into the inlet, through the airflow passage and to expel it via the outlet. A set of infrared emitting heating elements is located in the airflow passage behind a screen or glass panel and arranged both to radiate heat directly outwardly from the housing and to heat air in the airflow passage. Additional resistance heating elements are located in the airflow passage. The apparatus has a control system including a user interface, and is arranged to control the operation of the impeller and the two different kinds of heating elements in response to user input. The apparatus includes a heatsink associated with the infrared heating elements, which is located so that air passing through the airflow passage contacts the heatsink. The control system is arranged, in at least one mode of operation, to pre-heat the heatsink by operating the infrared heating elements prior to operating the impeller.

BACKGROUND OF THE INVENTION

THIS invention relates to a drying device or apparatus which can be used for drying a person's body after bathing or showering, for example.

SUMMARY OF THE INVENTION

According to the invention there is provided drying apparatus including a housing, the housing defining an air inlet, at least one airflow passage, and at least one air outlet; an impeller arranged to draw air into the inlet, through the airflow passage and to expel it via the outlet; at least one first heating element located in or adjacent to the airflow passage and arranged both to radiate heat directly outwardly from the housing and to heat air in the airflow passage; and a control system including a user interface and arranged to control the operation of the impeller and said at least one first heating element in response to a user input.

The drying apparatus may include a heatsink associated with said at least one first heating element and located so that air passing through the airflow passage contacts the heatsink, the control system being arranged, in at least one mode of operation, to pre-heat the heatsink by operating said at least one first heating element prior to operating the impeller.

Preferably, the first heating element comprises an infrared emitting element operable to generate an infrared output with a wavelength in a predetermined range, typically 7 to 14 microns.

The apparatus may include a plurality of infrared emitting elements located one above the other and arranged to emit infrared radiation towards a user of the apparatus.

The plurality of infrared emitting elements may be located behind a cover defining a part of the airflow passage, the cover being substantially transparent to infrared radiation.

The apparatus may include at least one second heating element located in or adjacent to the airflow passage and arranged to be operated selectively to heat air in the airflow passage.

Said at least one second heating element may comprise a resistance heating element, for example.

The control system is preferably arranged to operate said at least one first heating element, said at least one second heating element and said impeller selectively so as to limit the maximum power consumption of the drying apparatus to below a predetermined value.

In an embodiment of the apparatus, the control system is arranged to receive a user input selecting one of a plurality of pre-programmed operating modes, each operating mode being defined by a different combination of operating conditions for the first and second heating elements and the impeller.

The apparatus may include an ultraviolet light source in or adjacent to the airflow passage and arranged to sterilize air passing through the airflow passage.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a pictorial view of a drying device according to the invention;

FIG. 2 is a sectional side view on the line 2-2 in FIG. 1;

FIG. 3 is a section on the line 3-3 in FIG. 1;

FIG. 4 is a section on the line 4-4 in FIG. 1;

FIG. 5 is a simplified schematic block diagram of a control system of the drying device;

FIGS. 6 to 9 are flow diagrams illustrating the functioning of the apparatus in use; and

FIGS. 10( a) To 10(c) are waveform diagrams illustrating a power control scheme utilised by the control system of the device.

DESCRIPTION OF PREFERRED EMBODIMENTS

The drying device illustrated in FIGS. 1 to 4 comprises a housing or cabinet 10 which is generally rectangular in front elevation and which is of the same general height as a human, typically in the range of 1.5 to 2 meters tall. The housing is designed to be as shallow as possible and has a typical front to back depth of approximately 20 cm.

On its front surface 12, the drying device has a central, upright cover panel 14 which covers a plurality of infrared emitters (see below) and which is transparent to infrared radiation. The panel 14 can comprise, for example, suitable glass or a metal mesh.

On either side of the panel 14 are sets of adjustable louvres 16 and 18 which are normally closed, as illustrated, but which are opened in use to emit a flow of heated air towards a user of the device.

At the upper end of the housing 10 is a large display panel 20 with loud speakers 22 and 24 on either side of it. The loudspeakers form part of an optional audio and/or video system that can be included in the device. For example, the system can include a radio or TV tuner, a docking station for an iPod™ or other portable music player, or other conventional audio visual technology. The display panel 20 displays the status of the drying device and serves as part of a user interface in conjunction with a remote control unit 26. The display panel can comprise a liquid crystal display (LCD) or any other suitable type of display. Low voltage display technologies are preferred due to the fact that the device is likely to be used in a humid environment.

As can be seen from FIG. 1, the drying device has a neat and sleek appearance and is designed to be as unobtrusive as possible when installed in a bathroom or another desired location, typically against a wall.

The housing 10 may be fixed to a wall or other support, or can be provided with wheels or rollers to permit it to be moved about as required.

As best shown in FIGS. 2 and 3, the housing defines an inlet 28 for air at the lower end of its front surface 12. From the inlet, a tortuous airflow passage is defined within the interior of the housing. Air entering the inlet 28 is first drawn up a central inlet passage 30 which is defined between the panel 14 and an upright heatsink structure 32 located within the housing. Mounted on the heatsink structure are four infrared emitting panels 34, one above the other. Air reaching the top of the inlet passage 30 then flows down a further passage 36 defined between a finned rear surface of the heatsink structure and the rear surface 38 of the housing. Vertical fins 40 formed on the rear of the heatsink structure, which is typically an aluminum extrusion, extend into the passage 36 so that air passing downwardly through the passage 36 contacts the fins.

An ultraviolet emitting fluorescent tube 42 is mounted vertically in the passage 36 so that air passing through the passage 36 is subjected to UV light. The purpose of the UV lamp is to sterilize air passing through the device, and also to sterilize the interior of the housing 10.

At the lower end of the passage 36, near the base 44 of the housing 10, is a centrally located centrifugal fan 46 which has a forward facing inlet 48. Other types of fan could be used instead. The lower end of the airflow passage 36 opens into a chamber or plenum 50 below the heatsink structure 32, directing air to the inlet 48 of the fan 46.

The fan 46 has a pair of opposed outlets 52.1 and 52.2 which direct air into respective passages 54 and 56 in the base of the device. The passages 54 and 56 have short horizontal portions which turn through 90 degrees to define vertical, tubular air distribution conduits 58 and 60 which distribute air upwardly in the housing adjacent to the respective sets of louvres 16 and 18. In each of the conduits 58 and 60, a respective vertically extending slot 62 and 64 releases air from the conduit outwardly in the direction of the arrows in FIG. 3 when the louvres are opened.

To sum up airflow in the device, therefore, ambient air enters the device via the inlet 28 at the front of the housing, travels upwardly through the inlet airflow passage 30 past the infrared emitters 34 and the forward facing surface of the heatsink structure 32, down the airflow passage 36, past the finned rearward facing surface of the heating structure 32 and the ultraviolet lamp 42, to the chamber 50 adjacent the inlet of the centrifugal fan 46. From the fan 46, air is expelled into the respective passages 54 and 56, and up the vertical conduits 58 and 60, from which it is released by the respective slots 62 and 64 and the sets of louvres 16 and 18 from the front of the housing.

Within the conduits 58 and 60 are located resistance heating coils 66 and 68 which can be operated to increase the temperature of air passing through the conduits in use.

The conduits 58 and 60 are rotatable about their long axes, through about 90 degrees, so that the direction of the airstreams emitted via the sets of louvres 16 and 18 can be continuously swung back and forth from left to right in use, in opposite directions, or adjusted to a preferred static direction. The sets of louvres themselves are also adjustable to allow the device to cater for users of different height, for example. Both the conduits and the louvres are moved by drive mechanisms comprising small electric motors and suitable gearing or drive linkages. When the device is not in use, the louvres are closed, preventing excess dust and moisture from entering the device and presenting a neat appearance.

The operation of the device and its control system will now be described in greater detail.

Conventional drying devices using a flow of heated air, such as hand dryers used in public toilets, for example, typically comprise a fan and one or more heating coils. When the device is actuated, whether by a switch mounted on the housing of the device or by a sensor detecting the presence of a users' hands, for example, the fan is operated and the heating coils are connected to the AC mains electrical supply, generating the required stream of hot air.

Conventional hand drying devices of this kind typically have a power consumption in the range of 1.6 to 3 kW. If a device of this general kind is scaled up sufficiently to be able to provide a strong flow of sufficiently warm air to dry a users' entire body effectively, its power consumption will be substantially greater and could approach or exceed 10 kW. Although this can, in principle, be done, installation of such a device will then require a dedicated electrical feed (and possibly a three-phase supply). If it is desired to make the device usable in existing premises, it is necessary to limit the peak power consumption of the unit to a level that can safely be supplied by a single conventional wall outlet. For example, in South Africa, where the nominal AC mains voltage is 220V and conventional wall outlets are rated at 15 A, the maximum power consumption of the device must be limited to 3.3 kW.

The total power consumption of the infrared panels 34, the heating coils 66 and 68, the fan 46, the UV light 42 and the other electrical and electronic components of the prototype drying device of the invention was in the region of 5 kW. It therefore becomes necessary to manage the power consumption of the various components of the device to ensure that a safe maximum predetermined power consumption value of approximately 3 kW is not exceeded at any time.

In addition, in order to control the wavelength of infrared radiation emitted by the infrared emitting panels 34, it is necessary to control their temperature and thus the power dissipated in these panels.

Referring now to FIG. 5, which is an overall schematic block diagram of the control system of the drying device, the control system is seen to comprise a main control module 70 and a user interface 72. The user interface comprises the remote control unit 26 and the display 20, as well as a sensor (not shown) responsible to the remote control. The control module 70 is microprocessor-based and will typically comprise a suitable microprocessor with associated read only memory (ROM) in which software controlling the operation of the device is stored, and random access memory (RAM) for storing user preferences and settings, and other temporary data.

As indicated in FIG. 5, the control module receives three user selected inputs as well as a number of feedback signals from sensors in the device.

The Inputs to the Control Module are:

-   -   1. User selection: Temperature     -   2. User selection: Mode     -   3. User selection: Outlet air speed     -   4. Feedback: Fan speed     -   5. Feedback: Inlet air temperature     -   6. Feedback: Outlet air temperature     -   7. Feedback: Internal casing temperature     -   8. Feedback: Fault conditions in Air heater coil, IR panel, or         UV power modules

The control module also generates several outputs, both to the user interface 72 and to various circuits and control modules of the device.

Outputs from the Control Module are:

-   -   1. Control: IR panel power     -   2 Control: Air coil power     -   3. Control: Fan speed     -   4. Control: UV control     -   5. User interface: fault     -   6. User interface: outlet air temperature     -   7. User interface: IR wavelength parameter

Apart from the above mentioned microprocessor based control module, the control system of the drying device includes a number of sensor units and a number of power modules for controlling the operation of the various electrically powered components of the device. Thus, an infrared (IR) power module 74 is provided to control the power supplied to the infrared emitting panels 34, a heating coil power module 76 is provided to control the electrical supply to the heating coils 66 and 68, a fan power module 78 is provided to control the operation of the centrifugal fan 46 and a UV power module 80 is provided to control the operation of the UV lamp 42.

In addition, the control module receives a number of input and/or feedback signals, including signals from a number of temperature sensors. An outlet air temperature sensor 82 provides an outlet air temperature signal via a measurement circuit 34, and similar temperature sensors 86 and 88 which measure the temperature of the inlet airstream and the internal temperature within the housing of the device provide respective signals to the control module via measurement circuits 90 and 92.

The entire control system is powered by a mains-derived power supply of a conventonal nature (not shown).

The drying device has a number of operating modes which can be selected by a user via the user interface 72. The following predetermined modes were programmed into the prototype unit:

-   -   Immediate air heat: Air heater coils on maximum power, blower         fan on to create design air flow rate, power to IR panels         modulated.     -   Immediate IR heat: IR panels on maximum power, power to air         heater coils modulated, blower fan on low.     -   Auto heat (uses preheat): blower fan will start when sufficient         preheat time has elapsed to ensure that outlet air will be at         user defined temperature with blower fan operating at user         defined speed. Power to air heater coils and IR panels modulated         according to user temperature selection.     -   Sauna: Fan speed zero, air coils zero, panels operated at 175 W         per panel.     -   Timed: combines fan speed, air heating coils power, and IR panel         power in a predetermined profile.

It can be seen that the various modes or profiles are determined by different combinations of operating conditions for the infrared emitting panels, the heating coils and the fan. It will be appreciated by those skilled in the art that other predetermined operating modes can be devised and that the described modes are purely exemplary.

In each mode, the control module monitors the various inputs, including user settings, and controls the operation of the relevant components of the device via the respective power modules in accordance with an overall controlling algorithm. The overall algorithm includes total power output limiting, infrared wavelength control of the IR panels, correlation of temperature mappings to detect possible dangerous operating regions, failure monitoring (for example, fan speed not following fan speed control signal), determination of infrared panel temperature from timing and power supply data, and profiling of other parameters such as fan speed rate of change of switch-on to avoid uncomfortably high outlet air temperatures.

In the prototype device, it is a feature of the control method that no temperature feedback is required from the infrared panels. Instead, the control module contains detailed mappings of the infrared panel warm-up and operating temperatures in terms of time and input power, which are used to determine panel temperature.

From this information, it is possible to determine (using data supplied by the infrared panel manufacturers) the wavelength of infrared light emitted by the panels 34 in the different operating modes. Thus, in the “sauna” mode, the infrared panels are operated so as to emit infrared radiation in a preferred spectrum, typically in the range of 7 to 14 microns.

In the prototype unit, Ceramicx FTE 500 infrared emitters were used, which are rated for operation at 500 W. A graph published by the manufacturer, showing the output spectral power density against wavelength of the unit, indicates a peak in the region of 6 microns when operating at its rated power. However, by modulating the power fed to the unit, and running it at a power in the range of 175 to 250 W, an infrared output in the desired wavelength range is obtained.

Apart from the abovementioned control signals, the power modules 74, 76, 78 and 80 are arranged to provide feedback signals to the control modules 70 indicative of fault conditions that may arise. Such fault conditions include zero current draw by the relevant component, over-temperature of the respective power module or excessive current draw by the component in question. In the case of the infrared power module 74, the power module detects zero current draw or excessive current draw by any of the panels, thus enabling failure of one of the four panels to be detected.

The power modules control the power to the respective components in response to control signals from the control module. Modulation of the power supplied to the components is achieved by controlling the shape of the AC waveform supplied to the applicable component. The power modules comprise triacs or dual silicon controlled rectifiers (SCRs) and associated circuitry such as snubbers. Where the component is to be operated at full power, the full AC waveform is applied. To reduce the power output of the component, the AC waveform is progressively truncated. In this way, the control module is able to supply accurately the required power to the relevant component. FIGS. 10( a) and (b) show truncated AC waveforms corresponding to 25% and 50% power, whereas FIG. 10( c) shows a full AC waveform corresponding to 100% power.

The operating modes and sequences of the described device are set out diagrammatically in the flowcharts of FIGS. 6 to 9.

A significant feature of the device is a preheating function which operates the infrared emitters 34, causing them to heat the heatsink structure 32. Being a substantial aluminum extrusion, the heatsink structure can store a significant amount of heat. This allows the temperature of the output airflow to be increased, for a given airflow rate, or alternatively allows the airflow rate to be increased for a given output air temperature. The “autoheat” operating mode makes use of this feature, first operating the infrared units 34 to raise the temperature of the heatsink (taking into account a user selected outlet air temperature) and then starting the fan 46 once sufficient preheating has taken place. The heating elements 66 and 68 are then operated to further heat the preheated air, with the power to the infrared panels and the heating coils being modulated to maintain overall power consumption below the predetermined maximum level.

The heating device can also be operated in a “sauna” mode in which it relies entirely on the infrared output of the IR emitters 34, or the other modes referred to above, so that a user can select a preferred mode according to circumstances.

It will be appreciated that the above described drying device is versatile and efficient, and enables effective drying to be achieved notwithstanding a limited maximum input power consumption. 

1-11. (canceled)
 12. Drying apparatus including a housing, the housing defining an air inlet, at least one airflow passage, and at least one air outlet; an impeller arranged to draw air into the inlet, through the airflow passage and to expel it via the outlet; at least one first heating element located in or adjacent to the airflow passage and arranged both to radiate heat directly outwardly from the housing and to heat air in the airflow passage; and a control system including a user interface and arranged to control the operation of the impeller and said at least one first heating element in response to a user input, the apparatus including a heatsink associated with said at least one first heating element and located so that air passing through the airflow passage contacts the heatsink, the control system being arranged, in at least one mode of operation, to pre-heat the heatsink by operating said at least one first heating element prior to operating the impeller.
 13. Drying apparatus according to claim 12, wherein said at least one first heating element comprises an infrared emitting element operable to generate an infrared output with a wavelength in a predetermined range.
 14. Drying apparatus according to claim 12, wherein the predetermined range is 7 to 14 microns.
 15. Drying apparatus according to claim 12, including a plurality of infrared emitting elements located one above the other and arranged to emit infrared radiation toward a user of the apparatus.
 16. Drying apparatus according to claim 15, wherein the plurality of infrared emitting elements are located behind a cover defining a part of the airflow passage, the cover being substantially transparent to infrared radiation.
 17. Drying apparatus according to claim 12, including at least one second heating element located in or adjacent to the airflow passage and arranged to be operated selectively to heat air in the airflow passage.
 18. Drying apparatus according to claim 17, wherein said at least one second heating element comprises a resistance heating element.
 19. Drying apparatus according to claim 17, wherein the control system is arranged to operate said at least one first heating element, said at least one second heating element and said impeller selectively so as to limit the maximum power consumption of the drying apparatus to below a predetermined value.
 20. Drying apparatus according to claim 19, wherein the control system is arranged to receive a user input selecting one of a plurality of pre-programmed operating modes, each operating mode being defined by a different combination of operating conditions for the first and second heating elements and the impeller.
 21. Drying apparatus according to claim 12, including an ultraviolet light source in or adjacent to the airflow passage and arranged to sterilize air passing through the airflow passage. 